vect: Ensure SLP nodes don't end up in multiple BB partitions [PR106787]
Commit Message
In the PR we have two REDUC_PLUS SLP instances that share a common
load of stride 4. Each instance also has a unique contiguous load.
Initially all three loads are out of order, so have a nontrivial
load permutation. The layout pass puts them in order instead,
For the two contiguous loads it is possible to do this by adjusting the
SLP_LOAD_PERMUTATION to be { 0, 1, 2, 3 }. But a SLP_LOAD_PERMUTATION
of { 0, 4, 8, 12 } is rejected as unsupported, so the pass creates a
separate VEC_PERM_EXPR instead.
Later the 4-stride load's initial SLP_LOAD_PERMUTATION is rejected too,
so that the load gets replaced by an external node built from scalars.
We then have an external node feeding a VEC_PERM_EXPR.
VEC_PERM_EXPRs created in this way do not have any associated
SLP_TREE_SCALAR_STMTS. This means that they do not affect the
decision about which nodes should be in which subgraph for costing
purposes. If the VEC_PERM_EXPR is fed by a vect_external_def,
then the VEC_PERM_EXPR's input doesn't affect that decision either.
The net effect is that a shared VEC_PERM_EXPR fed by an external def
can appear in more than one subgraph. This triggered an ICE in
vect_schedule_node, which (rightly) expects to be called no more
than once for the same internal def.
There seemed to be many possible fixes, including:
(1) Replace unsupported loads with external defs *before* doing
the layout optimisation. This would avoid the need for the
VEC_PERM_EXPR altogether.
(2) If the target doesn't support a load in its original layout,
stop the layout optimisation from checking whether the target
supports loads in any new candidate layout. In other words,
treat all layouts as if they were supported whenever the
original layout is not in fact supported.
I'd rather not do this. In principle, the layout optimisation
could convert an unsupported layout to a supported one.
Selectively ignoring target support would work against that.
We could try to look specifically for loads that will need
to be decomposed, but that just seems like admitting that
things are happening in the wrong order.
(3) Add SLP_TREE_SCALAR_STMTS to VEC_PERM_EXPRs.
That would be OK for this case, but wouldn't be possible
for external defs that represent existing vectors.
(4) Make vect_schedule_slp share SCC info between subgraphs.
It feels like that's working around the partitioning problem
rather than a real fix though.
(5) Directly ensure that internal def nodes belong to a single
subgraph.
(1) is probably the best long-term fix, but (5) is much simpler.
The subgraph partitioning code already has a hash set to record
which nodes have been visited; we just need to convert that to a
map from nodes to instances instead.
Tested on aarch64-linux-gnu and x86_64-linux-gnu. OK to install?
Richard
gcc/
PR tree-optimization/106787
* tree-vect-slp.cc (vect_map_to_instance): New function, split out
from...
(vect_bb_partition_graph_r): ...here. Replace the visited set
with a map from nodes to instances. Ensure that a node only
appears in one partition.
(vect_bb_partition_graph): Update accordingly.
gcc/testsuite/
* gcc.dg/vect/bb-slp-layout-19.c: New test.
---
gcc/testsuite/gcc.dg/vect/bb-slp-layout-19.c | 34 ++++++++++
gcc/tree-vect-slp.cc | 69 ++++++++++++--------
2 files changed, 77 insertions(+), 26 deletions(-)
create mode 100644 gcc/testsuite/gcc.dg/vect/bb-slp-layout-19.c
Comments
On Fri, 2 Sep 2022, Richard Sandiford wrote:
> In the PR we have two REDUC_PLUS SLP instances that share a common
> load of stride 4. Each instance also has a unique contiguous load.
>
> Initially all three loads are out of order, so have a nontrivial
> load permutation. The layout pass puts them in order instead,
> For the two contiguous loads it is possible to do this by adjusting the
> SLP_LOAD_PERMUTATION to be { 0, 1, 2, 3 }. But a SLP_LOAD_PERMUTATION
> of { 0, 4, 8, 12 } is rejected as unsupported, so the pass creates a
> separate VEC_PERM_EXPR instead.
>
> Later the 4-stride load's initial SLP_LOAD_PERMUTATION is rejected too,
> so that the load gets replaced by an external node built from scalars.
> We then have an external node feeding a VEC_PERM_EXPR.
>
> VEC_PERM_EXPRs created in this way do not have any associated
> SLP_TREE_SCALAR_STMTS. This means that they do not affect the
> decision about which nodes should be in which subgraph for costing
> purposes. If the VEC_PERM_EXPR is fed by a vect_external_def,
> then the VEC_PERM_EXPR's input doesn't affect that decision either.
>
> The net effect is that a shared VEC_PERM_EXPR fed by an external def
> can appear in more than one subgraph. This triggered an ICE in
> vect_schedule_node, which (rightly) expects to be called no more
> than once for the same internal def.
>
> There seemed to be many possible fixes, including:
>
> (1) Replace unsupported loads with external defs *before* doing
> the layout optimisation. This would avoid the need for the
> VEC_PERM_EXPR altogether.
>
> (2) If the target doesn't support a load in its original layout,
> stop the layout optimisation from checking whether the target
> supports loads in any new candidate layout. In other words,
> treat all layouts as if they were supported whenever the
> original layout is not in fact supported.
>
> I'd rather not do this. In principle, the layout optimisation
> could convert an unsupported layout to a supported one.
> Selectively ignoring target support would work against that.
>
> We could try to look specifically for loads that will need
> to be decomposed, but that just seems like admitting that
> things are happening in the wrong order.
>
> (3) Add SLP_TREE_SCALAR_STMTS to VEC_PERM_EXPRs.
>
> That would be OK for this case, but wouldn't be possible
> for external defs that represent existing vectors.
In general it's good to provide SLP_TREE_SCALAR_STMTS when we
can, but yes, that's not a fix for the actual problem.
> (4) Make vect_schedule_slp share SCC info between subgraphs.
>
> It feels like that's working around the partitioning problem
> rather than a real fix though.
>
> (5) Directly ensure that internal def nodes belong to a single
> subgraph.
>
> (1) is probably the best long-term fix, but (5) is much simpler.
> The subgraph partitioning code already has a hash set to record
> which nodes have been visited; we just need to convert that to a
> map from nodes to instances instead.
Agreed.
> Tested on aarch64-linux-gnu and x86_64-linux-gnu. OK to install?
OK.
Thanks,
Richard.
> Richard
>
>
> gcc/
> PR tree-optimization/106787
> * tree-vect-slp.cc (vect_map_to_instance): New function, split out
> from...
> (vect_bb_partition_graph_r): ...here. Replace the visited set
> with a map from nodes to instances. Ensure that a node only
> appears in one partition.
> (vect_bb_partition_graph): Update accordingly.
>
> gcc/testsuite/
> * gcc.dg/vect/bb-slp-layout-19.c: New test.
> ---
> gcc/testsuite/gcc.dg/vect/bb-slp-layout-19.c | 34 ++++++++++
> gcc/tree-vect-slp.cc | 69 ++++++++++++--------
> 2 files changed, 77 insertions(+), 26 deletions(-)
> create mode 100644 gcc/testsuite/gcc.dg/vect/bb-slp-layout-19.c
>
> diff --git a/gcc/testsuite/gcc.dg/vect/bb-slp-layout-19.c b/gcc/testsuite/gcc.dg/vect/bb-slp-layout-19.c
> new file mode 100644
> index 00000000000..f075a83a25b
> --- /dev/null
> +++ b/gcc/testsuite/gcc.dg/vect/bb-slp-layout-19.c
> @@ -0,0 +1,34 @@
> +/* { dg-do compile } */
> +/* { dg-additional-options "-fno-tree-loop-vectorize" } */
> +
> +extern int a[][4], b[][4], c[][4], d[4], e[4];
> +void f()
> +{
> + int t0 = a[0][3];
> + int t1 = a[1][3];
> + int t2 = a[2][3];
> + int t3 = a[3][3];
> + int a0 = 0, a1 = 0, a2 = 0, a3 = 0, b0 = 0, b1 = 0, b2 = 0, b3 = 0;
> + for (int j = 0; j < 100; ++j)
> + for (int i = 0; i < 400; i += 4)
> + {
> + a0 += b[i][3] * t0;
> + a1 += b[i][2] * t1;
> + a2 += b[i][1] * t2;
> + a3 += b[i][0] * t3;
> + b0 += c[i][3] * t0;
> + b1 += c[i][2] * t1;
> + b2 += c[i][1] * t2;
> + b3 += c[i][0] * t3;
> + }
> + d[0] = a0;
> + d[1] = a1;
> + d[2] = a2;
> + d[3] = a3;
> + e[0] = b0;
> + e[1] = b1;
> + e[2] = b2;
> + e[3] = b3;
> +}
> +
> +/* { dg-final { scan-tree-dump-times "add new stmt: \[^\\n\\r\]* = VEC_PERM_EXPR" 3 "slp1" { target { vect_int_mult && vect_perm } } } } */
> diff --git a/gcc/tree-vect-slp.cc b/gcc/tree-vect-slp.cc
> index 1cf79eee4a6..59ec66a6f96 100644
> --- a/gcc/tree-vect-slp.cc
> +++ b/gcc/tree-vect-slp.cc
> @@ -6435,47 +6435,64 @@ get_ultimate_leader (slp_instance instance,
> return instance;
> }
>
> +namespace {
> +/* Subroutine of vect_bb_partition_graph_r. Map KEY to INSTANCE in
> + KEY_TO_INSTANCE, making INSTANCE the leader of any previous mapping
> + for KEY. Return true if KEY was already in KEY_TO_INSTANCE.
> +
> + INSTANCE_LEADER is as for get_ultimate_leader. */
> +
> +template<typename T>
> +bool
> +vect_map_to_instance (slp_instance instance, T key,
> + hash_map<T, slp_instance> &key_to_instance,
> + hash_map<slp_instance, slp_instance> &instance_leader)
> +{
> + bool existed_p;
> + slp_instance &key_instance = key_to_instance.get_or_insert (key, &existed_p);
> + if (!existed_p)
> + ;
> + else if (key_instance != instance)
> + {
> + /* If we're running into a previously marked key make us the
> + leader of the current ultimate leader. This keeps the
> + leader chain acyclic and works even when the current instance
> + connects two previously independent graph parts. */
> + slp_instance key_leader
> + = get_ultimate_leader (key_instance, instance_leader);
> + if (key_leader != instance)
> + instance_leader.put (key_leader, instance);
> + }
> + key_instance = instance;
> + return existed_p;
> +}
> +}
> +
> /* Worker of vect_bb_partition_graph, recurse on NODE. */
>
> static void
> vect_bb_partition_graph_r (bb_vec_info bb_vinfo,
> slp_instance instance, slp_tree node,
> hash_map<stmt_vec_info, slp_instance> &stmt_to_instance,
> - hash_map<slp_instance, slp_instance> &instance_leader,
> - hash_set<slp_tree> &visited)
> + hash_map<slp_tree, slp_instance> &node_to_instance,
> + hash_map<slp_instance, slp_instance> &instance_leader)
> {
> stmt_vec_info stmt_info;
> unsigned i;
>
> FOR_EACH_VEC_ELT (SLP_TREE_SCALAR_STMTS (node), i, stmt_info)
> - {
> - bool existed_p;
> - slp_instance &stmt_instance
> - = stmt_to_instance.get_or_insert (stmt_info, &existed_p);
> - if (!existed_p)
> - ;
> - else if (stmt_instance != instance)
> - {
> - /* If we're running into a previously marked stmt make us the
> - leader of the current ultimate leader. This keeps the
> - leader chain acyclic and works even when the current instance
> - connects two previously independent graph parts. */
> - slp_instance stmt_leader
> - = get_ultimate_leader (stmt_instance, instance_leader);
> - if (stmt_leader != instance)
> - instance_leader.put (stmt_leader, instance);
> - }
> - stmt_instance = instance;
> - }
> + vect_map_to_instance (instance, stmt_info, stmt_to_instance,
> + instance_leader);
>
> - if (!SLP_TREE_SCALAR_STMTS (node).is_empty () && visited.add (node))
> + if (vect_map_to_instance (instance, node, node_to_instance,
> + instance_leader))
> return;
>
> slp_tree child;
> FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
> if (child && SLP_TREE_DEF_TYPE (child) == vect_internal_def)
> vect_bb_partition_graph_r (bb_vinfo, instance, child, stmt_to_instance,
> - instance_leader, visited);
> + node_to_instance, instance_leader);
> }
>
> /* Partition the SLP graph into pieces that can be costed independently. */
> @@ -6489,16 +6506,16 @@ vect_bb_partition_graph (bb_vec_info bb_vinfo)
> corresponding SLP graph entry and upon visiting a previously
> marked stmt, make the stmts leader the current SLP graph entry. */
> hash_map<stmt_vec_info, slp_instance> stmt_to_instance;
> + hash_map<slp_tree, slp_instance> node_to_instance;
> hash_map<slp_instance, slp_instance> instance_leader;
> - hash_set<slp_tree> visited;
> slp_instance instance;
> for (unsigned i = 0; bb_vinfo->slp_instances.iterate (i, &instance); ++i)
> {
> instance_leader.put (instance, instance);
> vect_bb_partition_graph_r (bb_vinfo,
> instance, SLP_INSTANCE_TREE (instance),
> - stmt_to_instance, instance_leader,
> - visited);
> + stmt_to_instance, node_to_instance,
> + instance_leader);
> }
>
> /* Then collect entries to each independent subgraph. */
>
new file mode 100644
@@ -0,0 +1,34 @@
+/* { dg-do compile } */
+/* { dg-additional-options "-fno-tree-loop-vectorize" } */
+
+extern int a[][4], b[][4], c[][4], d[4], e[4];
+void f()
+{
+ int t0 = a[0][3];
+ int t1 = a[1][3];
+ int t2 = a[2][3];
+ int t3 = a[3][3];
+ int a0 = 0, a1 = 0, a2 = 0, a3 = 0, b0 = 0, b1 = 0, b2 = 0, b3 = 0;
+ for (int j = 0; j < 100; ++j)
+ for (int i = 0; i < 400; i += 4)
+ {
+ a0 += b[i][3] * t0;
+ a1 += b[i][2] * t1;
+ a2 += b[i][1] * t2;
+ a3 += b[i][0] * t3;
+ b0 += c[i][3] * t0;
+ b1 += c[i][2] * t1;
+ b2 += c[i][1] * t2;
+ b3 += c[i][0] * t3;
+ }
+ d[0] = a0;
+ d[1] = a1;
+ d[2] = a2;
+ d[3] = a3;
+ e[0] = b0;
+ e[1] = b1;
+ e[2] = b2;
+ e[3] = b3;
+}
+
+/* { dg-final { scan-tree-dump-times "add new stmt: \[^\\n\\r\]* = VEC_PERM_EXPR" 3 "slp1" { target { vect_int_mult && vect_perm } } } } */
@@ -6435,47 +6435,64 @@ get_ultimate_leader (slp_instance instance,
return instance;
}
+namespace {
+/* Subroutine of vect_bb_partition_graph_r. Map KEY to INSTANCE in
+ KEY_TO_INSTANCE, making INSTANCE the leader of any previous mapping
+ for KEY. Return true if KEY was already in KEY_TO_INSTANCE.
+
+ INSTANCE_LEADER is as for get_ultimate_leader. */
+
+template<typename T>
+bool
+vect_map_to_instance (slp_instance instance, T key,
+ hash_map<T, slp_instance> &key_to_instance,
+ hash_map<slp_instance, slp_instance> &instance_leader)
+{
+ bool existed_p;
+ slp_instance &key_instance = key_to_instance.get_or_insert (key, &existed_p);
+ if (!existed_p)
+ ;
+ else if (key_instance != instance)
+ {
+ /* If we're running into a previously marked key make us the
+ leader of the current ultimate leader. This keeps the
+ leader chain acyclic and works even when the current instance
+ connects two previously independent graph parts. */
+ slp_instance key_leader
+ = get_ultimate_leader (key_instance, instance_leader);
+ if (key_leader != instance)
+ instance_leader.put (key_leader, instance);
+ }
+ key_instance = instance;
+ return existed_p;
+}
+}
+
/* Worker of vect_bb_partition_graph, recurse on NODE. */
static void
vect_bb_partition_graph_r (bb_vec_info bb_vinfo,
slp_instance instance, slp_tree node,
hash_map<stmt_vec_info, slp_instance> &stmt_to_instance,
- hash_map<slp_instance, slp_instance> &instance_leader,
- hash_set<slp_tree> &visited)
+ hash_map<slp_tree, slp_instance> &node_to_instance,
+ hash_map<slp_instance, slp_instance> &instance_leader)
{
stmt_vec_info stmt_info;
unsigned i;
FOR_EACH_VEC_ELT (SLP_TREE_SCALAR_STMTS (node), i, stmt_info)
- {
- bool existed_p;
- slp_instance &stmt_instance
- = stmt_to_instance.get_or_insert (stmt_info, &existed_p);
- if (!existed_p)
- ;
- else if (stmt_instance != instance)
- {
- /* If we're running into a previously marked stmt make us the
- leader of the current ultimate leader. This keeps the
- leader chain acyclic and works even when the current instance
- connects two previously independent graph parts. */
- slp_instance stmt_leader
- = get_ultimate_leader (stmt_instance, instance_leader);
- if (stmt_leader != instance)
- instance_leader.put (stmt_leader, instance);
- }
- stmt_instance = instance;
- }
+ vect_map_to_instance (instance, stmt_info, stmt_to_instance,
+ instance_leader);
- if (!SLP_TREE_SCALAR_STMTS (node).is_empty () && visited.add (node))
+ if (vect_map_to_instance (instance, node, node_to_instance,
+ instance_leader))
return;
slp_tree child;
FOR_EACH_VEC_ELT (SLP_TREE_CHILDREN (node), i, child)
if (child && SLP_TREE_DEF_TYPE (child) == vect_internal_def)
vect_bb_partition_graph_r (bb_vinfo, instance, child, stmt_to_instance,
- instance_leader, visited);
+ node_to_instance, instance_leader);
}
/* Partition the SLP graph into pieces that can be costed independently. */
@@ -6489,16 +6506,16 @@ vect_bb_partition_graph (bb_vec_info bb_vinfo)
corresponding SLP graph entry and upon visiting a previously
marked stmt, make the stmts leader the current SLP graph entry. */
hash_map<stmt_vec_info, slp_instance> stmt_to_instance;
+ hash_map<slp_tree, slp_instance> node_to_instance;
hash_map<slp_instance, slp_instance> instance_leader;
- hash_set<slp_tree> visited;
slp_instance instance;
for (unsigned i = 0; bb_vinfo->slp_instances.iterate (i, &instance); ++i)
{
instance_leader.put (instance, instance);
vect_bb_partition_graph_r (bb_vinfo,
instance, SLP_INSTANCE_TREE (instance),
- stmt_to_instance, instance_leader,
- visited);
+ stmt_to_instance, node_to_instance,
+ instance_leader);
}
/* Then collect entries to each independent subgraph. */